Rise of a Meteoroid Thermal in the Earth’s Atmosphere
A set of nonlinear differential equations describing the parameters during the rise of a thermal (its velocity, radius, and excess temperature) as a function of height and time is numerically solved. It is found that the rise velocity varies nonmonotonically: it increases rapidly at first and its in...
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description | A set of nonlinear differential equations describing the parameters during the rise of a thermal (its velocity, radius, and excess temperature) as a function of height and time is numerically solved. It is found that the rise velocity varies nonmonotonically: it increases rapidly at first and its increase rate decreases with the increasing drag of the incoming air; for a long time (tens to thousands of seconds), this velocity remains close to the maximum (approximately 10…180 m/s), and then it decreases relatively slowly (for hundreds to thousands of seconds) to zero. It is shown that the more the thermal is heated and the larger its size, the faster it rises and reaches higher altitudes for a longer time. During the rise, the radius of the thermal increases by a factor of 6…25 depending on its initial size and initial temperature due to the entrained cold air. The greater the current radius value, the higher the increase rate of the thermal radius. The size of a small thermal increases by more times than that of a big thermal. The thermal radius increases until it is completely stopped. Less heated thermals rise more slowly, entrain smaller amounts of cold air, and increase less in size. It is shown that the cooling rate is proportional to the thermal rise velocity and is maximum when the maximum value of this velocity is reached. The warmer thermal cools more rapidly than the less heated one. The thermal cooling rate depends relatively weakly on its initial size. The limitations of the used model (the uniformity and isothermality of the atmosphere and neglect of the effect of thermal radiation, wind, and turbulence on the thermal cooling) are discussed. Despite the limitations, in general, the model is confirmed by the results of observations of the rise of the thermal generated during the explosion of the Chelyabinsk meteoroid. |
doi_str_mv | 10.3103/S0884591318040025 |
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F. ; Mylovanov, Yu. B.</creator><creatorcontrib>Chernogor, L. F. ; Mylovanov, Yu. B.</creatorcontrib><description>A set of nonlinear differential equations describing the parameters during the rise of a thermal (its velocity, radius, and excess temperature) as a function of height and time is numerically solved. It is found that the rise velocity varies nonmonotonically: it increases rapidly at first and its increase rate decreases with the increasing drag of the incoming air; for a long time (tens to thousands of seconds), this velocity remains close to the maximum (approximately 10…180 m/s), and then it decreases relatively slowly (for hundreds to thousands of seconds) to zero. It is shown that the more the thermal is heated and the larger its size, the faster it rises and reaches higher altitudes for a longer time. During the rise, the radius of the thermal increases by a factor of 6…25 depending on its initial size and initial temperature due to the entrained cold air. The greater the current radius value, the higher the increase rate of the thermal radius. The size of a small thermal increases by more times than that of a big thermal. The thermal radius increases until it is completely stopped. Less heated thermals rise more slowly, entrain smaller amounts of cold air, and increase less in size. It is shown that the cooling rate is proportional to the thermal rise velocity and is maximum when the maximum value of this velocity is reached. The warmer thermal cools more rapidly than the less heated one. The thermal cooling rate depends relatively weakly on its initial size. The limitations of the used model (the uniformity and isothermality of the atmosphere and neglect of the effect of thermal radiation, wind, and turbulence on the thermal cooling) are discussed. Despite the limitations, in general, the model is confirmed by the results of observations of the rise of the thermal generated during the explosion of the Chelyabinsk meteoroid.</description><identifier>ISSN: 0884-5913</identifier><identifier>EISSN: 1934-8401</identifier><identifier>DOI: 10.3103/S0884591318040025</identifier><language>eng</language><publisher>Moscow: Pleiades Publishing</publisher><subject>Aerodynamics ; Air entrainment ; Astronomy ; Atmosphere ; Cooling ; Cooling rate ; Differential equations ; Dynamics and Physics of Bodies of the Solar System ; Mathematical models ; Meteoroids ; Meteors & meteorites ; Nonlinear differential equations ; Nonlinear equations ; Observations and Techniques ; Physics ; Physics and Astronomy ; Radiation ; Thermal radiation ; Thermals ; Velocity ; Wind effects</subject><ispartof>Kinematics and physics of celestial bodies, 2018-07, Vol.34 (4), p.198-206</ispartof><rights>Allerton Press, Inc. 2018</rights><rights>Kinematics and Physics of Celestial Bodies is a copyright of Springer, (2018). All Rights Reserved.</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c316t-efcd5cd37107a561b1bcbfd9da2488f8b0fd9d105545de2ce7db820ec14ac833</citedby><cites>FETCH-LOGICAL-c316t-efcd5cd37107a561b1bcbfd9da2488f8b0fd9d105545de2ce7db820ec14ac833</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://link.springer.com/content/pdf/10.3103/S0884591318040025$$EPDF$$P50$$Gspringer$$H</linktopdf><linktohtml>$$Uhttps://link.springer.com/10.3103/S0884591318040025$$EHTML$$P50$$Gspringer$$H</linktohtml><link.rule.ids>314,780,784,27924,27925,41488,42557,51319</link.rule.ids></links><search><creatorcontrib>Chernogor, L. F.</creatorcontrib><creatorcontrib>Mylovanov, Yu. B.</creatorcontrib><title>Rise of a Meteoroid Thermal in the Earth’s Atmosphere</title><title>Kinematics and physics of celestial bodies</title><addtitle>Kinemat. Phys. Celest. Bodies</addtitle><description>A set of nonlinear differential equations describing the parameters during the rise of a thermal (its velocity, radius, and excess temperature) as a function of height and time is numerically solved. It is found that the rise velocity varies nonmonotonically: it increases rapidly at first and its increase rate decreases with the increasing drag of the incoming air; for a long time (tens to thousands of seconds), this velocity remains close to the maximum (approximately 10…180 m/s), and then it decreases relatively slowly (for hundreds to thousands of seconds) to zero. It is shown that the more the thermal is heated and the larger its size, the faster it rises and reaches higher altitudes for a longer time. During the rise, the radius of the thermal increases by a factor of 6…25 depending on its initial size and initial temperature due to the entrained cold air. The greater the current radius value, the higher the increase rate of the thermal radius. The size of a small thermal increases by more times than that of a big thermal. The thermal radius increases until it is completely stopped. Less heated thermals rise more slowly, entrain smaller amounts of cold air, and increase less in size. It is shown that the cooling rate is proportional to the thermal rise velocity and is maximum when the maximum value of this velocity is reached. The warmer thermal cools more rapidly than the less heated one. The thermal cooling rate depends relatively weakly on its initial size. The limitations of the used model (the uniformity and isothermality of the atmosphere and neglect of the effect of thermal radiation, wind, and turbulence on the thermal cooling) are discussed. Despite the limitations, in general, the model is confirmed by the results of observations of the rise of the thermal generated during the explosion of the Chelyabinsk meteoroid.</description><subject>Aerodynamics</subject><subject>Air entrainment</subject><subject>Astronomy</subject><subject>Atmosphere</subject><subject>Cooling</subject><subject>Cooling rate</subject><subject>Differential equations</subject><subject>Dynamics and Physics of Bodies of the Solar System</subject><subject>Mathematical models</subject><subject>Meteoroids</subject><subject>Meteors & meteorites</subject><subject>Nonlinear differential equations</subject><subject>Nonlinear equations</subject><subject>Observations and Techniques</subject><subject>Physics</subject><subject>Physics and Astronomy</subject><subject>Radiation</subject><subject>Thermal radiation</subject><subject>Thermals</subject><subject>Velocity</subject><subject>Wind effects</subject><issn>0884-5913</issn><issn>1934-8401</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><sourceid>ABUWG</sourceid><sourceid>AFKRA</sourceid><sourceid>AZQEC</sourceid><sourceid>BENPR</sourceid><sourceid>CCPQU</sourceid><sourceid>DWQXO</sourceid><sourceid>GNUQQ</sourceid><recordid>eNp1kM1Kw0AUhQdRsFYfwN2A6-i985NMlqXUH6gI2n2YzNzYlLZTZ9KFO1_D1_NJTKjgQlxdDuc758Jh7BLhWiLImxcwRukSJRpQAEIfsRGWUmVGAR6z0WBng3_KzlJaAehclGrEiuc2EQ8Nt_yROgoxtJ4vlhQ3ds3bLe-WxGc2dsuvj8_EJ90mpF3v0jk7aew60cXPHbPF7Wwxvc_mT3cP08k8cxLzLqPGee28LBAKq3OssXZ140tvhTKmMTUMAkFrpT0JR4WvjQByqKwzUo7Z1aF2F8PbnlJXrcI-bvuPlYCykEUuEXsKD5SLIaVITbWL7cbG9wqhGuap_szTZ8Qhk3p2-0rxt_n_0DdyLmas</recordid><startdate>20180701</startdate><enddate>20180701</enddate><creator>Chernogor, L. 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B.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c316t-efcd5cd37107a561b1bcbfd9da2488f8b0fd9d105545de2ce7db820ec14ac833</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2018</creationdate><topic>Aerodynamics</topic><topic>Air entrainment</topic><topic>Astronomy</topic><topic>Atmosphere</topic><topic>Cooling</topic><topic>Cooling rate</topic><topic>Differential equations</topic><topic>Dynamics and Physics of Bodies of the Solar System</topic><topic>Mathematical models</topic><topic>Meteoroids</topic><topic>Meteors & meteorites</topic><topic>Nonlinear differential equations</topic><topic>Nonlinear equations</topic><topic>Observations and Techniques</topic><topic>Physics</topic><topic>Physics and Astronomy</topic><topic>Radiation</topic><topic>Thermal radiation</topic><topic>Thermals</topic><topic>Velocity</topic><topic>Wind effects</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Chernogor, L. 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F.</au><au>Mylovanov, Yu. B.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Rise of a Meteoroid Thermal in the Earth’s Atmosphere</atitle><jtitle>Kinematics and physics of celestial bodies</jtitle><stitle>Kinemat. Phys. Celest. Bodies</stitle><date>2018-07-01</date><risdate>2018</risdate><volume>34</volume><issue>4</issue><spage>198</spage><epage>206</epage><pages>198-206</pages><issn>0884-5913</issn><eissn>1934-8401</eissn><abstract>A set of nonlinear differential equations describing the parameters during the rise of a thermal (its velocity, radius, and excess temperature) as a function of height and time is numerically solved. It is found that the rise velocity varies nonmonotonically: it increases rapidly at first and its increase rate decreases with the increasing drag of the incoming air; for a long time (tens to thousands of seconds), this velocity remains close to the maximum (approximately 10…180 m/s), and then it decreases relatively slowly (for hundreds to thousands of seconds) to zero. It is shown that the more the thermal is heated and the larger its size, the faster it rises and reaches higher altitudes for a longer time. During the rise, the radius of the thermal increases by a factor of 6…25 depending on its initial size and initial temperature due to the entrained cold air. The greater the current radius value, the higher the increase rate of the thermal radius. The size of a small thermal increases by more times than that of a big thermal. The thermal radius increases until it is completely stopped. Less heated thermals rise more slowly, entrain smaller amounts of cold air, and increase less in size. It is shown that the cooling rate is proportional to the thermal rise velocity and is maximum when the maximum value of this velocity is reached. The warmer thermal cools more rapidly than the less heated one. The thermal cooling rate depends relatively weakly on its initial size. The limitations of the used model (the uniformity and isothermality of the atmosphere and neglect of the effect of thermal radiation, wind, and turbulence on the thermal cooling) are discussed. Despite the limitations, in general, the model is confirmed by the results of observations of the rise of the thermal generated during the explosion of the Chelyabinsk meteoroid.</abstract><cop>Moscow</cop><pub>Pleiades Publishing</pub><doi>10.3103/S0884591318040025</doi><tpages>9</tpages></addata></record> |
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subjects | Aerodynamics Air entrainment Astronomy Atmosphere Cooling Cooling rate Differential equations Dynamics and Physics of Bodies of the Solar System Mathematical models Meteoroids Meteors & meteorites Nonlinear differential equations Nonlinear equations Observations and Techniques Physics Physics and Astronomy Radiation Thermal radiation Thermals Velocity Wind effects |
title | Rise of a Meteoroid Thermal in the Earth’s Atmosphere |
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